Regulation of Programmed Ribosomal Frameshifting by Co-Translational Refolding RNA Hairpins

RNA structures are unwound for decoding. In the process, they can pause the elongating ribosome for regulation. An example is the stimulation of -1 programmed ribosomal frameshifting, leading to 3′ direction slippage of the reading-frame during elongation, by specific pseudoknot stimulators downstream of the frameshifting site. By investigating a recently identified regulatory element upstream of the SARS coronavirus (SARS-CoV) −1 frameshifting site, it is shown that a minimal functional element with hairpin forming potential is sufficient to down-regulate−1 frameshifting activity. Mutagenesis to disrupt or restore base pairs in the potential hairpin stem reveals that base-pair formation is required for−1 frameshifting attenuation in vitro and in 293T cells. The attenuation efficiency of a hairpin is determined by its stability and proximity to the frameshifting site; however, it is insensitive to E site sequence variation. Additionally, using a dual luciferase assay, it can be shown that a hairpin stimulated +1 frameshifting when placed upstream of a +1 shifty site in yeast. The investigations indicate that the hairpin is indeed a cis-acting programmed reading-frame switch modulator. This result provides insight into mechanisms governing−1 frameshifting stimulation and attenuation. Since the upstream hairpin is unwound (by a marching ribosome) before the downstream stimulator, this study’s findings suggest a new mode of translational regulation that is mediated by the reformed stem of a ribosomal unwound RNA hairpin during elongation.     

A sequence required for -1 ribosomal frameshifting located four kilobases downstream of the frameshift site

Programmed ribosomal frameshifting allows one mRNA to encode regulate expression of, multiple open reading frames (ORFs). The polymerase encoded by ORF 2 of Barley yellow dwarf virus (BYDV) is expressed via minus one (-1) frameshifting from the overlapping ORF 1. Previously, this appeared to be mediated by a 116 nt RNA sequence that contains canonical -1 frameshift signals including a shifty heptanucleotide followed by a highly structured region. However, unlike known -1 frameshift signals, the reporter system required the zero frame stop codon and did not require a consensus shifty site for expression of the -1 ORF. In contrast, full-length viral RNA required a functional shifty site for frameshifting in wheat germ extract, while the stop codon was not required. Increasing translation initiation efficiency by addition of a 5' cap on the naturally uncapped viral RNA, decreased the frameshift rate. Unlike any other known RNA, a region four kilobases downstream of the frameshift site was required for frameshifting. This included an essential 55 base tract followed by a 179 base tract that contributed to full frameshifting. The effects of most mutations on frameshifting correlated with the ability of viral RNA to replicate in oat protoplasts, indicating that the wheat germ extract accurately reflected control of BYDV RNA translation in the infected cell. However, the overall frameshift rate appeared to be higher in infected cells, based on immunodetection of viral proteins. These findings show that use of short recoding sequences out of context in reporter constructs may overlook distant signals. Most importantly, the remarkably long-distance interaction reported here suggests the presence of a novel structure that can facilitate ribosomal frameshifting.     

Structural and functional studies of retroviral RNA pseudoknots involved in ribosomal frameshifting: nucleotides at the junction of the two stems are important for efficient ribosomal frameshifting.

Ribosomal frameshifting, a translational mechanism used during retroviral replication, involves a directed change in reading frame at a specific site at a defined frequency. Such programmed frameshifting at the mouse mammary tumor virus (MMTV) gag-pro shift site requires two mRNA signals: a heptanucleotide shifty sequence and a pseudoknot structure positioned downstream. Using in vitro translation assays and enzymatic and chemical probes for RNA structure, we have defined features of the pseudoknot that promote efficient frameshifting. Heterologous RNA structures, e.g. a hairpin, a tRNA or a synthetic pseudoknot, substituted downstream of the shifty site fail to promote frameshifting, suggesting that specific features of the MMTV pseudoknot are important for function. Site-directed mutations of the MMTV pseudoknot indicate that the pseudoknot junction, including an unpaired adenine nucleotide between the two stems, provides a specific structural determinant for efficient frameshifting. Pseudoknots derived from other retroviruses (i.e. the feline immunodeficiency virus and the simian retrovirus type 1) also promote frameshifting at the MMTV gag-pro shift site, dependent on the same structure at the junction of the two stems.     

An extended signal involved in eukaryotic -1 frameshifting operates through modification of the E site tRNA

By using a sensitive search program based on hidden Markov models (HMM), we identified 74 viruses carrying frameshift sites among 1500 fully sequenced virus genomes. These viruses are clustered in specific families or genera. Sequence analysis of the frameshift sites identified here, along with previously characterized sites, identified a strong bias toward the two nucleotides 5' of the shifty heptamer signal. Functional analysis in the yeast Saccharomyces cerevisiae demonstrated that high frameshifting efficiency is correlated with the presence of a Psi39 modification in the tRNA present in the E site of the ribosome at the time of frameshifting. These results demonstrate that an extended signal is involved in eukaryotic frameshifting and suggest additional interactions between tRNAs and the ribosome during decoding.     

Mutational analysis of the "slippery-sequence" component of a coronavirus ribosomal frameshifting signal.

The ribosomal frameshift signal in the genomic RNA of the coronavirus IBV is composed of two elements, a heptanucleotide "slippery-sequence" and a downstream RNA pseudoknot. We have investigated the kinds of slippery sequence that can function at the IBV frameshift site by analysing the frameshifting properties of a series of slippery-sequence mutants. We firstly confirmed that the site of frameshifting in IBV was at the heptanucleotide stretch UUUAAAC, and then used our knowledge of the pseudoknot structure and a suitable reporter gene to prepare an expression construct that allowed both the magnitude and direction of ribosomal frameshifting to be determined for candidate slippery sequences. Our results show that in almost all of the sequences tested, frameshifting is strictly into the -1 reading frame. Monotonous runs of nucleotides, however, gave detectable levels of a -2/+1 frameshift product, and U stretches in particular gave significant levels (2% to 21%). Preliminary evidence suggests that the RNA pseudoknot may play a role in influencing frameshift direction. The spectrum of slip-sequences tested in this analysis included all those known or suspected to be utilized in vivo. Our results indicate that triplets of A, C, G and U are functional when decoded in the ribosomal P-site following slippage (XXXYYYN) although C triplets were the least effective. In the A-site (XXYYYYN), triplets of C and G were non-functional. The identity of the nucleotide at position 7 of the slippery sequence (XXXYYYN) was found to be a critical determinant of frameshift efficiency and we show that a hierarchy of frameshifting exists for A-site codons. These observations lead us to suggest that ribosomal frameshifting at a particular site is determined, at least in part, by the strength of the interaction of normal cellular tRNAs with the A-site codon and does not necessarily involve specialized "shifty" tRNAs.     

Translational frameshifting at the gag-pol junction of human immunodeficiency virus type 1 is not increased in infected T-lymphoid cells.

A frameshift event is necessary for expression of the products of the pol gene in a number of retroviruses, including human immunodeficiency virus type 1 (HIV-1). The basic signals necessary for frameshifting consist of a shifty sequence in which the ribosome slips and a downstream stimulatory structure which can be either a stem-loop or a pseudoknot. In HIV-1, much attention has been paid to the frameshift site itself, and only recently has the role of the downstream structure been examined. Here we used a luciferase-based experimental system to analyze in vivo the cis and trans factors potentially involved in controlling frameshifting efficiency at the gag-pol junction of HIV-1. We demonstrated that high-level frameshifting is dependent on the presence of a palindromic region located downstream of the site where the frameshift event takes place. Frameshifting efficiencies were found to be identical in mouse fibroblasts and the natural host cells of the virus, i.e., CD4+ human lymphoid cells. Furthermore, no increase in frameshifting was observed upon virus infection. Previous observations have shown that viral infection leads to specific alteration of tRNAs involved in translation of shifty sites (D. Hatfield, Y.-X. Feng, B.J. Lee, A. Rein, J.G. Levin, and S. Oroszlan, Virology 173:736-742, 1989). The results presented here strongly suggest that these modifications do not affect frameshifting efficiency.     

Context rules of rightward overlapping reading.

We have investigated the mechanism and sequence context rules governing ribosome frameshifting promoted by aminoacyl-tRNA limitation. In the case of one shifty sequence, frameshifting promoted by lysyl-tRNA limitation occurs at the sequence AAG C and is due to rightward movement of the ribosome so as to read the AGC triplet overlapping the hungry codon from the right. The frequency of this event is unaffected by sequence elements more than three bases to the left (upstream) or two bases to the right (downstream) of the hungry codon, and only slightly affected by the identity of the base two bases to the right. It is strongly affected by the base immediately to the right of the hungry codon, which becomes the wobble base of the shifted triplet; and by the third base of the hungry codon, even though the two synonyms (AAG and AAA) call for the same aminoacyl-tRNA; and by the identity of the base immediately to the left of the hungry codon. The latter result suggests that the aminoacyl-tRNA in the P site affects the maintenance of reading frame at the adjacent A site of the ribosome. However, the DNA sequence makes it seem unlikely that the P-site tRNA shifts to the right in concert with the A-site tRNA, a mechanism that can account for leftward frameshifting (in the opposite direction) in retroviral translation. The specificity of sequence determinants of leftwing versus rightwing frameshifting is discussed.     

Programmed +1 frameshifting stimulated by complementarity between a downstream mRNA sequence and an error-correcting region of rRNA

Like most retroviruses and retrotransposons, the retrotransposon Ty3 expresses its pol gene analog (POL3) as a translational fusion to the upstream gag analog (GAG3). The Gag3-Pol3 fusion occurs by frameshifting during translation of the mRNA that encodes the two separate but overlapping ORFs. We showed previously that the shift occurs by out-of-frame binding of a normal aminoacyl-tRNA in the ribosomal A site caused by an aberrant codonoanticodon interaction in the P site. This event is unlike all previously described programmed translational frameshifts because it does not require tRNA slippage between cognate or near-cognate codons in the mRNA. A sequence of 15 nt distal to the frameshift site stimulates frameshifting 7.5-fold. Here we show that the Ty3 stimulator acts as an unstructured region to stimulate frameshifting. Its function depends on strict spacing from the site of frameshifting. Finally, the stimulator increases frameshifting dependent on sense codon-induced pausing, but has no effect on frameshifting dependent on pauses induced by nonsense codons. Complementarity between the stimulator and a portion of the accuracy center of the ribosome, Helix 18, implies that the stimulator may directly disrupt error correction by the ribosome.     

Maintenance of the correct open reading frame by the ribosome

During translation, a string of non-overlapping triplet codons in messenger RNA is decoded into protein. The ability of a ribosome to decode mRNA without shifting between reading frames is a strict requirement for accurate protein biosynthesis. Despite enormous progress in understanding the mechanism of transfer RNA selection, the mechanism by which the correct reading frame is maintained remains unclear. In this report, evidence is presented that supports the idea that the translational frame is controlled mainly by the stability of codon–anticodon interactions at the P site. The relative instability of such interactions may lead to dissociation of the P-site tRNA from its codon, and formation of a complex with an overlapping codon, the process known as P-site tRNA slippage. We propose that this process is central to all known cases of +1 ribosomal frameshifting, including that required for the decoding of the yeast transposable element Ty3. An earlier model for the decoding of this element proposed 'out-of-frame' binding of A-site tRNA without preceding P-site tRNA slippage.     

The nucleic acid-binding zinc finger protein of potato virus M is translated by internal initiation as well as by ribosomal frameshifting involving a shifty stop codon and a novel mechanism of P-site slippage.

The genes for the capsid protein CP and the nucleic acid-binding 12K protein (pr12) of potato virus M (PVM) constitute the 3' terminal gene cluster of the PVM RNA genome. Both proteins are presumably translated from a single subgenomic RNA. We have identified two translational strategies operating in pr12 gene expression. Internal initiation at the first and the second AUG codon of the pr12 coding sequence results in the synthesis of the 12K protein. In addition the protein is produced as a CP/12K transframe protein by ribosomal frameshifting. For these studies parts of the CP and pr12 coding sequences including the putative frameshift region were introduced into an internal position of the beta-glucuronidase gene. Mutational analyses in conjunction with in vitro translation experiments identified a homopolymeric string of four adenosine nucleotides which together with a 3' flanking UGA stop codon were required for efficient frameshifting. The signal AAAAUGA is the first frameshift signal with a shifty stop codon to be analyzed in the eukaryotic system. Substitution of the four consecutive adenosine nucleotides by UUUU increased the efficiency of frameshifting, while substitution by GGGG or CCCC dramatically reduced the synthesis of the transframe protein. Also, UAA and UAG could replace the opal stop codon without effect on the frameshifting event, but mutation of UGA to the sense codon UGG inhibited transframe protein formation. These findings suggest that the mechanism of ribosomal frameshifting at the PVM signal is different from the one described by the 'simultaneous slippage' model in that only the string of four adenosine nucleotides represents the slippery sequence involved in a -1 P-site slippage.     

Maintaining the ribosomal reading frame: the influence of the E site during translational regulation of release factor 2

Maintenance of the translation reading frame is one of the most remarkable achievements of the ribosome while decoding the information of an mRNA. Loss of the reading frame through spontaneous frameshifting occurs with a frequency of one in 30,000 amino acid incorporations. However, at many recoding sites, the mechanism that controls reading frame maintenance is switched off. One such example is the programmed +1 frameshift site of the prfB gene encoding the termination factor RF2, in which slippage into the forward frame by one nucleotide can attain an efficiency of approximately 100%, namely, four orders of magnitude higher than normally observed. Here, using the RF2 frameshift window, we demonstrate that premature release of the E site tRNA from the ribosome is coupled with high-level frameshifting. Consistently, in a minimal system, the presence of the E site tRNA prevents the +1 frameshift event, illustrating the importance of the E site for reading-frame maintenance.     

Characterization of an efficient coronavirus ribosomal frameshifting signal: requirement for an RNA pseudoknot

The genomic RNA of the coronavirus IBV contains an efficient ribosomal frameshifting signal at the junction of two overlapping open reading frames. We have defined by deletion analysis an 86 nucleotide sequence encompassing the overlap region which is sufficient to allow frameshifting in a heterologous context. The upstream boundary of the signal consists of the sequence UUUAAAC, which is the likely site of ribosomal slippage. We show by creation of complementary nucleotide changes that the RNA downstream of this "slippery" sequence folds into a tertiary structure termed a pseudoknot, the formation of which is essential for efficient frameshifting.     

The Highly Conserved Codon following the Slippery Sequence Supports ?1 Frameshift Efficiency at the HIV-1 Frameshift Site

HIV-1 utilises −1 programmed ribosomal frameshifting to translate structural and enzymatic domains in a defined proportion required for replication. A slippery sequence, U UUU UUA, and a stem-loop are well-defined RNA features modulating −1 frameshifting in HIV-1. The GGG glycine codon immediately following the slippery sequence (the ‘intercodon’) contributes structurally to the start of the stem-loop but has no defined role in current models of the frameshift mechanism, as slippage is inferred to occur before the intercodon has reached the ribosomal decoding site. This GGG codon is highly conserved in natural isolates of HIV. When the natural intercodon was replaced with a stop codon two different decoding molecules—eRF1 protein or a cognate suppressor tRNA—were able to access and decode the intercodon prior to −1 frameshifting. This implies significant slippage occurs when the intercodon is in the (perhaps distorted) ribosomal A site. We accommodate the influence of the intercodon in a model of frame maintenance versus frameshifting in HIV-1.     

tRNA slippage at the tmRNA resume codon

The bacterial ribosome does not initiate translation on the mRNA portion of tmRNA; instead translation that had begun on a separate mRNA molecule resumes at a particular triplet on tmRNA (the resume codon). For at least two tRNAs that could pair with both the resume and -2 triplets on mutant tmRNAs, UAA (stop) as the second codon induced high-frequency -2 slippage on the resume codon in the P site. The frameshift product was not detected when the -2 base was altered. Deficiency for ribosomal L9 protein, which affects other cases of frameshifting, had no significant effect. A special feature of this frameshifting is its dependence on a particular context, that of the tmRNA resume codon; it failed on the same sequence in a regular mRNA, and, more strikingly, at the second tmRNA codon. This focuses attention on the peculiar features expected of the slippage-prone state, such as unusual E-site filling, that might make the P-site resume codon:anticodon interaction especially unstable. Keywords: tmRNA; ribosome; frameshift; E site; translation     

A review on architecture of the gag-pol ribosomal frameshifting RNA in human immunodeficiency virus: a variability survey of virus genotypes

Programmed ‘-1’ ribosomal frameshifting is necessary for expressing the pol gene overlapped from a gag of human immunodeficiency virus. A viral RNA structure that requires base pairing across the overlapping sequence region suggests a mechanism of regulating ribosome and helicase traffic during expression. To get precise roles of an element around the frameshift site, a review on architecture of the frameshifting RNA is performed in combination of reported information with augments of a representative set of 19 viral samples. In spite of a different length for the viral RNAs, a canonical comparison on the element sequence allocation is performed for viewing variability associations between virus genotypes. Additionally, recent and historical insights recognized in frameshifting regulation are looked back as for indel and single nucleotide polymorphism of RNA. As specially noted, structural changes at a frameshift site, the spacer sequence, and a three-helix junction element, as well as two Watson–Crick base pairs near a bulge and a C–G pair close a loop, are the most vital strategies for the virus frameshifting regulations. All of structural changes, which are dependent upon specific sequence variations, facilitate an elucidation about the RNA element conformation-dependent mechanism for frameshifting. These facts on disrupting base pair interactions also allow solving the problem of competition between ribosome and helicase on a same RNA template, common to single-stranded RNA viruses. In a broad perspective, each new insight of frameshifting regulation in the competition systems introduced by the RNA element construct changes will offer a compelling target for antiviral therapy.     

Ribosomal Pausing at a Frameshifter RNA Pseudoknot Is Sensitive to Reading Phase but Shows Little Correlation with Frameshift Efficiency

Here we investigated ribosomal pausing at sites of programmed -1 ribosomal frameshifting, using translational elongation and ribosome heelprint assays. The site of pausing at the frameshift signal of infectious bronchitis virus (IBV) was determined and was consistent with an RNA pseudoknot-induced pause that placed the ribosomal P- and A-sites over the slippery sequence. Similarly, pausing at the simian retrovirus 1 gag/pol signal, which contains a different kind of frameshifter pseudoknot, also placed the ribosome over the slippery sequence, supporting a role for pausing in frameshifting. However, a simple correlation between pausing and frameshifting was lacking. Firstly, a stem-loop structure closely related to the IBV pseudoknot, although unable to stimulate efficient frameshifting, paused ribosomes to a similar extent and at the same place on the mRNA as a parental pseudoknot. Secondly, an identical pausing pattern was induced by two pseudoknots differing only by a single loop 2 nucleotide yet with different functionalities in frameshifting. The final observation arose from an assessment of the impact of reading phase on pausing. Given that ribosomes advance in triplet fashion, we tested whether the reading frame in which ribosomes encounter an RNA structure (the reading phase) would influence pausing. We found that the reading phase did influence pausing but unexpectedly, the mRNA with the pseudoknot in the phase which gave the least pausing was found to promote frameshifting more efficiently than the other variants. Overall, these experiments support the view that pausing alone is insufficient to mediate frameshifting and additional events are required. The phase dependence of pausing may be indicative of an activity in the ribosome that requires an optimal contact with mRNA secondary structures for efficient unwinding.     

Antisense-induced ribosomal frameshifting

Programmed ribosomal frameshifting provides a mechanism to decode information located in two overlapping reading frames by diverting a proportion of translating ribosomes into a second open reading frame (ORF). The result is the production of two proteins: the product of standard translation from ORF1 and an ORF1–ORF2 fusion protein. Such programmed frameshifting is commonly utilized as a gene expression mechanism in viruses that infect eukaryotic cells and in a subset of cellular genes. RNA secondary structures, consisting of pseudoknots or stem–loops, located downstream of the shift site often act as cis-stimulators of frameshifting. Here, we demonstrate for the first time that antisense oligonucleotides can functionally mimic these RNA structures to induce +1 ribosomal frameshifting when annealed downstream of the frameshift site, UCC UGA. Antisense-induced shifting of the ribosome into the +1 reading frame is highly efficient in both rabbit reticulocyte lysate translation reactions and in cultured mammalian cells. The efficiency of antisense-induced frameshifting at this site is responsive to the sequence context 5′ of the shift site and to polyamine levels.     

Secondary structures and starvation-induced frameshifting

We have examined the effect of a downstream secondary structure (the stem–loop sequence found downstream on the MMTV gag-pro frameshift site) on frameshifting at a bacterial shifty site (U UUC AUA) that responds strongly to a isoleucine-tRNA limitation. Our findings are as follows: (i) the downstream stem–loop has little effect on frameshifting in growing, unstarved cells; (ii) the stem–loop increases the frameshifting effect of isoleucine-tRNA limitation about fourfold, and this synergism is maximal with a distance of 5–9 nucleotides between the 'hungry' AUA codon and the stem–loop; and (iii) a stem–loop of different sequence at the same position has the same effect.     

Kinetics of ribosomal pausing during programmed -1 translational frameshifting

In the Saccharomyces cerevisiae double-stranded RNA virus, programmed -1 ribosomal frameshifting is responsible for translation of the second open reading frame of the essential viral RNA. A typical slippery site and downstream pseudoknot are necessary for this frameshifting event, and previous work has demonstrated that ribosomes pause over the slippery site. The translational intermediate associated with a ribosome paused at this position is detected, and, using in vitro translation and quantitative heelprinting, the rates of synthesis, the ribosomal pause time, the proportion of ribosomes paused at the slippery site, and the fraction of paused ribosomes that frameshift are estimated. About 10% of ribosomes pause at the slippery site in vitro, and some 60% of these continue in the -1 frame. Ribosomes that continue in the -1 frame pause about 10 times longer than it takes to complete a peptide bond in vitro. Altering the rate of translational initiation alters the rate of frameshifting in vivo. Our in vitro and in vivo experiments can best be interpreted to mean that there are three methods by which ribosomes pass the frameshift site, only one of which results in frameshifting.